.PP
The SYSRQ target allows one to remotely trigger sysrq on the local machine over
the network. This can be useful when vital parts of the machine hang, for
example an oops in a file system causing locks to be not released and processes
to get stuck as a result \(em if still possible, use /proc/sysrq-trigger. Even
when processes are stuck, interrupts are likely to be still processed, and as
such, sysrq can be triggered through incoming network packets.
.PP
The xt_SYSRQ implementation uses a salted hash and a sequence number to prevent
network sniffers from either guessing the password or replaying earlier
requests. The initial sequence number comes from the time of day so you will
have a small window of vulnerability should time go backwards at a reboot.
However, the file /sys/module/xt_SYSREQ/seqno can be used to both query and
update the current sequence number. Also, you should limit as to who can issue
commands using \fB\-s\fP and/or \fB\-m mac\fP, and also that the destination is
correct using \fB\-d\fP (to protect against potential broadcast packets),
noting that it is still short of MAC/IP spoofing:
.IP
\-A INPUT \-s 10.10.25.1 \-m mac \-\-mac\-source aa:bb:cc:dd:ee:ff \-d
10.10.25.7 \-p udp \-\-dport 9 \-j SYSRQ
.IP
(with IPsec) \-A INPUT \-s 10.10.25.1 \-d 10.10.25.7 \-m policy \-\-dir in
\-\-pol ipsec \-\-proto esp \-\-tunnel\-src 10.10.25.1 \-\-tunnel\-dst
10.10.25.7 \-p udp \-\-dport 9 \-j SYSRQ
.PP
You should also limit the rate at which connections can be received to limit
the CPU time taken by illegal requests, for example:
.IP
\-A INPUT \-s 10.10.25.1 \-m mac \-\-mac\-source aa:bb:cc:dd:ee:ff \-d
10.10.25.7 \-p udp \-\-dport 9 \-m limit \-\-limit 5/minute \-j SYSRQ
.PP
This extension does not take any options. The \fB\-p udp\fP options are
required.
.PP
The SYSRQ password can be changed through
/sys/module/xt_SYSRQ/parameters/password, for example:
.IP
echo \-n "password" >/sys/module/xt_SYSRQ/parameters/password
.PP
The module will not respond to sysrq requests until a password has been set.
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Alternatively, the password may be specified at modprobe time, but this is
insecure as people can possible see it through ps(1). You can use an option
line in e.g. /etc/modprobe.d/xt_sysrq if it is properly guarded, that is, only
readable by root.
.IP
options xt_SYSRQ password=cookies
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The hash algorithm can also be specified as a module option, for example, to
use SHA-256 instead of the default SHA-1:
.IP
options xt_SYSRQ hash=sha256
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The xt_SYSRQ module is normally silent unless a successful request is received,
but the \fIdebug\fP module parameter can be used to find exactly why a
seemingly correct request is not being processed.
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To trigger SYSRQ from a remote host, just use socat:
.PP
.nf
sysrq_key="s"  # the SysRq key(s)
password="password"
seqno="$(date +%s)"
salt="$(dd bs=12 count=1 if=/dev/urandom 2>/dev/null |
    openssl enc \-base64)"
ipaddr="2001:0db8:0000:0000:0000:ff00:0042:8329"
req="$sysrq_key,$seqno,$salt"
req="$req,$(echo \-n "$req,$ipaddr,$password" | sha1sum | cut \-c1\-40)"

echo "$req" | socat stdin udp\-sendto:$ipaddr:9
.fi
.PP
See the Linux docs for possible sysrq keys. Important ones are: re(b)oot,
power(o)ff, (s)ync file systems, (u)mount and remount readonly. More than one
sysrq key can be used at once, but bear in mind that, for example, a sync may
not complete before a subsequent reboot or poweroff.
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An IPv4 address should have no leading zeros, an IPv6 address should
be in the full expanded form (as shown above). The debug option will cause
output to be emitted in the same form.
.PP
The hashing scheme should be enough to prevent mis-use of SYSRQ in many
environments, but it is not perfect: take reasonable precautions to
protect your machines.
